Lane Marking Localization

ABSTRACT

Various embodiments of the present disclosure provide a system and method for lane marking localization that may be utilized by autonomous or semi-autonomous vehicles traveling within the lane. In an embodiment, the system comprises a locating device adapted to determine the vehicle&#39;s geographic location; a database; a region map; a response map; a camera; and a computer connected to the locating device, database, and camera, wherein the computer is adapted to: receive the region map, wherein the region map corresponds to a specified geographic location; generate the response map by receiving information from the camera, the information relating to the environment in which the vehicle is located; identifying lane markers observed by the camera; and plotting identified lane markers on the response map; compare the response map to the region map; and generate a predicted vehicle location based on the comparison of the response map and the region map.

BACKGROUND OF THE INVENTION 1. Field of Invention

The present disclosure relates to unmanned vehicle guidance and, more specifically, a system for and method of sensing a roadway lane.

2. Description of Related Art

Global positioning satellite (“GPS”) technology is widely used as a means for locating an automobile upon a roadway. As autonomous and semi-autonomous vehicles become more advanced, accurately knowing the vehicle's position in the roadway becomes critical. For example, self-driving cars by Volvo and Tesla have been easily confused by faded lane markers and other shabby road conditions. Further, current GPS technology is inaccurate. To achieve a fully autonomous self-driving vehicle requires the ability of a computer to determine the vehicle's lateral position within a roadway with great precision. Additionally, advanced driver-assistance systems (“ADAS”) benefit greatly from this ability. For example, lane keeping assistance (“LKA”) systems, lane departure warning (“LDW”) systems, and lane change assistance systems would be greatly benefited by accurately knowing the vehicle's lateral position within a lane. Other examples of ADAS systems include adaptive cruise control, adaptive light control, anti-lock braking systems, automatic parking, blind spot monitoring, collision avoidance systems, intersection detection, lane departure warning systems, parking sensors, turning assistance, and wrong-way driving warning.

A vehicle may utilize various levels of autonomous driving. For example, a first level of autonomous driving may assist a human driver during some driving tasks such as steering or engine acceleration/deceleration. A second level of autonomous driving may conduct some steering and acceleration/deceleration while the human driver monitors the driving environment and controls the remaining driving tasks. Such a system is referred to as a partially automated system. A third level of autonomous driving may conduct driving tasks and monitor the driving environment, but the human driver must be ready to retake control when the automated system requests. Such a system is generally referred to as a conditionally automated system. A fourth level of autonomous driving may drive the vehicle and monitor road conditions; the human driver does not need to take control but the system may only operate in specific conditions and environments such as inside of a factory, on a closed road course, or within a bounded area. Such a system is referred to as a highly automated system. A fifth level of autonomous driving may perform all driving and road-monitoring tasks in all driving conditions. Such a system is referred to as a fully-automated system.

Current technology relies on GPS technology to determine a vehicle's lateral position within a roadway. However, this method is susceptible to a high amount of drift—the lateral area around the vehicle that is within the technology's margin of error. The amount of drift in a given system is dependent on many factors including signal strength and the precision of the GPS hardware being used. Typical GPS devices aimed at the average consumer have a drift of about 10 meters. Even with the most precise instruments having the best signal strength, a system experiences a drift of 1-2 meters or more, which is unacceptable for self-driving vehicles.

To improve the accuracy of GPS positioning, current technology also employs an inertial measurement unit (“IMU”). An IMU is an electronic device that measures and reports a vehicle's specific force and angular rate using a combination of accelerometers and gyroscopes. However, even while being augmented with IMU's, current lateral locating methods and systems still experience a high amount of drift. For such a system to be useful in a self-driving vehicle, the resolution needs to be approximately 10 cm or less.

Therefore, what is needed is a system that can utilize GPS information and determine a vehicle's lateral position within a roadway with great accuracy. This need has heretofore remained unsatisfied.

SUMMARY OF THE INVENTION

The present disclosure overcomes these and other deficiencies of the prior art by providing a method for determining a vehicle's location comprising the steps of approximating the vehicle's region, receiving a region map from a database, wherein the region map corresponds to the vehicle's approximated region and comprises a plurality of region points indicating an expected roadway lane, receiving a response image generated by an imaging device, the response image comprising information relating to the vehicle's environment, generating a response map from the response image, the response map comprising a plurality of response points indicating the vehicle's location, comparing the response map to the region map, and predicting the vehicle's location based on the differences between the response points and the region points.

In another exemplary embodiment of the present disclosure, the vehicle's region may be approximated using a GPS device or an IMU device.

In another exemplary embodiment of the present disclosure, the step of generating a response map further comprises the steps of detecting lane markers in the response image, the lane markers pertaining to physical aspects contained in the response image, and plotting the response points on the response map, the response points indicating locations of the lane markers.

In another exemplary embodiment of the present disclosure, the method may further comprise the step of generating a confidence score.

In another exemplary embodiment of the present disclosure, the response image may be generated from radar sensing equipment, LIDAR sensing equipment, GPS sensing information, and/or images.

In another exemplary embodiment of the present disclosure, the region map and the response map may be compared at a selected frequency.

In another exemplary embodiment of the present disclosure, the selected frequency may be at least 20 cycles per second.

In another exemplary embodiment of the present disclosure, the method may further comprise the step of outputting the vehicle's predicted location to an ADAS.

In another exemplary embodiment of the preset disclosure, the imaging devices may comprise a plurality of imaging devices, each adapted to perceive different aspects of the vehicle's environment.

In overcoming the limitations currently available in the art, another exemplary embodiment provides a system for determining a vehicle's location on a roadway comprising a locating device adapted to determine a vehicle's geographic region, a database comprising a plurality of region maps, the region maps comprising a plurality of region points, an imaging device adapted to perceive information relating to the vehicle's environment, a processor operably connected to the locating device, the database, and the imaging device, the processor, at a predetermined frequency, adapted to receive, from the locating device, the vehicle's determined geographic region, receive, from the database, the region map corresponding to the vehicle's determined geographic region, receive, from the imaging device, information perceived relating to the vehicle's environment, generate a response map, the response map comprising a plurality of response points corresponding to lane markers detected within the response map, compare the response map to the region map, and determine the vehicle's predicted location based on the comparison of the region map and response map.

In another exemplary embodiment of the present disclosure, the locating device may comprise a GPS device or an IMU device.

In another exemplary embodiment of the present disclosure, the imaging device may comprise a camera or a LIDAR device.

In another exemplary embodiment of the present disclosure, the predetermined frequency is at least 20 cycles per second.

In another exemplary embodiment of the present invention, the processor may be further configured to output the vehicle's predicted location to an ADAS.

In another exemplary embodiment of the present disclosure, the processor nay be further configured to determine a confidence score.

In another exemplary embodiment of the present disclosure, the system may further comprise a plurality of imaging devices, each adapted to perceive different aspects of the vehicle's environment.

In some embodiments, the present disclosure provides various vehicle systems the ability to recognize and track lane markings, which, in turn, may be used to allow on-board monitors to detect and/or correct the vehicle's location. For example, the present disclosure may interact with a lane keeping assistance (“LKA”) system, lane departure warning (“LDW”) system, and lane change assistance system. Such examples may utilize the present disclosure because such systems need to know the relative position the vehicles within the ego-lane and/or the lane to the left/right.

The foregoing, and other features and advantages of the invention, will be apparent from the following, more particular description of the preferred embodiments of the invention, the accompanying drawings, and the claims.

BRIEF DESCRIPTION OF THE DRAWINGS

For a more complete understanding of the present disclosure, the objects and advantages thereof, reference is now made to the ensuing descriptions taken in connection with the accompanying drawings briefly described as follows:

FIG. 1 illustrates a system for determining a vehicle's position within a lane, according to an exemplary embodiment of the present disclosure;

FIG. 2 illustrates a method for determining a vehicle's position within a lane, according to an exemplary embodiment of the present disclosure;

FIG. 3A illustrates an image taken by the camera, according to an exemplary embodiment of the present disclosure;

FIG. 3B illustrates a response map, according to an exemplary embodiment of the present disclosure;

FIG. 3C illustrates a lane map, according to an exemplary embodiment of the present disclosure; and

FIG. 4 illustrates updated vehicle location, according to an exemplary embodiment of the present disclosure.

DETAILED DESCRIPTION OF EMBODIMENTS

Further features and advantages of the disclosure, as well as the structure and operation of various embodiments of the disclosure, are described in detail below with reference to the accompanying FIGS. 1-4. Although the disclosure is described in the context of a generic vehicle, the term vehicle refers to any type of motorized ground transport including, but not limited to, cars, trucks, carts, sleds, lifts, and rovers.

In an exemplary embodiment of the present disclosure, the system utilizes hardware including a camera, a database, and a computer, to iteratively update the vehicle's predicted location and to determine the vehicle's position relative to the lane of traffic in which it is traveling. In one embodiment, the camera is installed on the vehicle and its position and view angle are predetermined relative to the rest of the vehicle on which it is installed. For example, the camera may be installed on the roof of the vehicle at the centerline of the vehicle, and pointed in the direction of travel, i.e., forward, such that the camera is out of the view of the driver. The computer is configured to include the camera's position and orientation relative to the vehicle. The computer fetches data from the camera and generates a response map. The response map is generated by identifying and locating lane indicators depicted the camera's data. The computer fetches data from the database, including a region map. The region map comprises information previously gathered by a collection vehicle equipped with lane sensing devices including radar, LIDAR, GPS, and cameras. In such an embodiment, the collection vehicle, along with the equipment thereon, accurately determines the collection vehicle's location in relation to lane markers. Such lane markers include traditional lane markings such as lines painted in a roadway and reflectors. Lane markers may also include permanent or semi-permanent structures such as raised curbs, barricades, retaining walls, roadway shoulders, roadway barriers, bridges, buildings, street signs, tunnels, trees, any support structures thereof.

The present disclosure utilizes the collection vehicle's accurately determined roadway position relative to lane markers as a baseline to determine a subsequent vehicle's location within the same roadway at a similar longitudinal roadway position. For example, the subsequent vehicle may be referred to as the “target vehicle.” As the target vehicle moves down a roadway, it captures information to generate the response map. The response map comprises information similar to that of a region map. The target vehicle may have a lateral position within the roadway different from that of the collection vehicle's lateral position at the same longitudinal roadway position. The present disclosure determines the target vehicle's location within the roadway by comparing the response map—the location information captured by the target vehicle—against the region map—the location information captured by collection vehicle. In doing so, the target vehicle's lateral roadway position is accurately determined relative to (1) the lane indicators perceived by target vehicle and (2) the collection vehicle's accurately determined roadway position relative to the same lane indicators.

The computer compares the response map against the region map to determine a confidence score. The confidence score is a numerical representation of the differences between the response map and the region map; the greater the difference, the lower the confidence score. If the confidence score is below a predetermined threshold, the computer generates the vehicle's predicted position. The predicted position is generated by comparing the region map against the response map and determining the vehicle's likely position based on the relative perspectives of the response map and the region map. In another embodiment, the computer generates the vehicle's predicted position at any confidence score. The system may output the updated location information to another system. For example, the system may output the updated location information to the vehicle's self-driving automation system and/or an ADAS system installed on the vehicle. In another example, the system may output the updated location information to a database or another vehicle. Such a system may be implemented as part of an automated self-driving system that steers the vehicle in response to the updated location information. In another embodiment, such a system may be implemented as part of an ADAS.

In an exemplary embodiment of the present disclosure and with reference to FIG. 1, a system 100 is utilized as part of a vehicle to determine the vehicle's location within a lane. The system may comprise a GPS device 120 to provide an approximation of the vehicle's actual location and an IMU 110 to estimate the vehicle's speed and velocity. The system may also comprise a database 140 comprising environment data 130. The environment data 130 may comprise a plurality of region maps. The system may also comprise a camera 150 configured to perceive information relating to the vehicle's environment. The system may also comprise a computer 160 and an output device 170.

In an embodiment, the GPS device 120 gathers information comprising the latitude, longitude, and/or the position of the vehicle. In another embodiment, the GPS information comprises the vehicle's yaw angle and/or direction of travel. In another embodiment, the GPS information comprises a time and date stamp. The GPS device 120 may receive information from orbiting satellites that are widely used in the current state of the art. General GPS signaling and positioning is readily apparent to one skilled in the art.

The database 140 comprises environment data 130 obtained using GPS and/or radar, and/or light detection and ranging (“LIDAR”), and/or photographic cameras, and/or videographic cameras. In such an embodiment, a collection vehicle (not shown) comprises equipment including radar, LIDAR, GPS, and cameras. The equipment installed on the collection vehicle accurately gathers location information as it is driven down a roadway. This location information is uploaded to the database 140 and is used to create the environment data 130. The environment data 130 is used to identify physical structures that aid the system in determining a vehicle's position relative to those structures. For example, the environment data 130 may comprise location information relating to lane markers including lane separators, lane markings, and reflectors. In such an embodiment, the collection vehicle accurately determines its physical location relative to the lane markers. In another embodiment, the environment data 130 further comprises data relating to permanent or semi-permanent structures including bridges, signs, buildings, barriers, street lights, raised curbs, trees, support structures thereof, and other physical structures. In one embodiment, the database 140 is located remotely. In another embodiment, the database 140 is located on the vehicle. In another embodiment, the database 140 may comprise a plurality of local or remote databases, communicatively connected to one-another and to the computer 160.

The camera 150 may be installed on the vehicle having any orientation or view angle. For example, the camera 150 may be installed such that it points in the direction of travel, i.e., towards the front of the vehicle. In another embodiment, the camera 150 may be installed such that it points in a direction other than the direction of travel, i.e., towards the rear or sides of the vehicle. In one embodiment, the camera 150 comprises a video camera gathering video at a predetermined rate. In another embodiment, the camera 150 comprises a video camera with frame rate of at least 20 frames per second. In another embodiment, the camera 150 comprises a photographic camera capturing images at a predetermined rate. In an embodiment, the camera 150 comprises a photographic camera capturing images at rate of at least 10 frames per second. In another embodiment, the camera 150 may be configured to capture information beyond that visible to the human eye. For example, the camera 150 may be configured to capture infrared light and/or ultraviolet light. While a camera is disclosed herein, the disclosed subject matter is not limited to a camera comprising a lens and/or a light sensor or film. For example, the camera 150 may be a depth sensor. In such an embodiment, the camera 150 comprises a light-emitting device and a sensor capable of detecting the light emitted from that device. In such an embodiment, light-emitting device emits a plurality of beams of light, for example, infrared laser beams. The plurality of infrared lasers reflect light off of various surfaces and structures, for example, roadway reflectors and lane markers. The camera's 150 sensor detects the infrared lasers and generates a depth map of the environment perceived by the camera 150. Further, as disclosed here, the camera 150 may comprise a plurality of cameras pointed in the same or differing directions. In such an embodiment, the plurality of cameras may be installed at different locations on the vehicle.

The present disclosure includes a computer 160 for processing the data from the GPS 120, the database 140, and the camera 150. The computer 160 generates the vehicle's predicted location by comparing the vehicle's approximate location fetched from the GPS 120, the environment data 130 fetched from the database 140, and the information gathered from the camera 150. The environment data may include a region map (not shown). In one embodiment, the system uses the GPS 120 to determine an approximate location of the vehicle. The computer 160 fetches environment data 130 relating to the vehicle's approximate location, as determined by the GPS 120. The computer 160 fetches data from the camera 150. The computer 160 determines the vehicle's predicted location by comparing the environment data 130 against the data fetched from the camera 150.

In another embodiment, the computer 160 also determines a confidence score that correlates to how well the data fetched from the camera 150 matches the environment data 130 fetched from the GPS 120 and the database 140.

After the computer 160 determines the vehicle's predicted location, the computer 160 may output that information to an output device 170. For example, the computer 160 may output the vehicle's predicted location to self-driving automation system. In another embodiment, the computer 160 may output the vehicle's predicted location to an ADAS. In another embodiment, the computer 160 may output the vehicle's predicted location to a database.

FIG. 2 illustrates a method 200 for determining a vehicle's position within a lane, according to an exemplary embodiment of the disclosure. At step 210, a computer fetches GPS and/or IMU location information from an GPS device and/or an IMU device. At step 220, the computer generates a region map comprising previously-gathered information relating to the environment in which the vehicle is traveling. For example, the region map comprises information previously gathered by a collection vehicle using radar, LIDAR, GPS, and/or cameras. Such information pertained to the collection vehicle's location on a specific roadway relative to other roadways in the area, lane-specific information relative to the lane in which the collection vehicle is traveling, and information relating to the collection vehicle's speed, direction of travel, and/or velocity relative to the location information. In one embodiment, the computer generates the region map. In another embodiment, the computer receives the region map from a database.

At step 230, the system utilizes a camera installed on the vehicle. In one embodiment, the camera is installed on the vehicle having a predetermined viewing angle and orientation. For example, the camera is installed on the roof of the vehicle, centered on the vehicle's centerline, and pointing in the direction of travel, i.e., forward. The camera captures an image of the region in front of the vehicle. In another embodiment, the camera may capture video and/or photographic images at a predetermined frame rate. In another embodiment, the camera captures infrared and/or ultraviolet light. In one embodiment, the camera captures images at a predetermined rate. In another example, the camera captures images at a rate of at least 10 images per second.

At step 240, the system generates a response map based on information fetched from the camera. The response map may be generated in real-time or in near real-time. The response map may be generated on a predetermined interval, for example, 20 times per second. In one embodiment, the system uses an image fetched from the camera and identifies lane markers within the lanes of vehicle travel depicted in the image. The camera may identify other aspects of the roadway including, but not limited to, bridges, signs, barriers, street lights, and buildings. In one embodiment, the computer comprises computer-executable code configured to detect permanent and/or semi-permanent structures within a two-dimensional image. In such an embodiment, the computer analyzes the image captured from the camera and identifies lane indicators such as painted lines and reflectors. The computer may also identify other structures such as bridges, signs, barriers, street lights, and buildings. The computer may generate a response map on a predetermined interval. In one embodiment, the computer generates a response map at least ten times per second.

At step 250, the system generates the vehicle's predicted location and calculates a confidence score for determining the vehicle's lateral position within a lane. For example, the system determines the predicted location by comparing the region map against the response map. In such an embodiment, the system samples various points within the region map identifying lanes of vehicle travel. The system samples the response map and identifies lanes of travel depicted therein. The system then compares this sampled region map to the response map and generates the vehicle's predicted location based on the differences in the perspectives of the region and response maps. In such an embodiment, the system takes the GPS/IMU information, the region map, and the response map as arguments in calculating the vehicle's predicted location. For example, if the region map is substantially the same as the response map but skewed to the left, the system's comparison recognizes the vehicle's actual position must be to the right of the GPS location. The system generates a predicted vehicle location based those differences.

In another embodiment, at step 250, the system calculates a confidence score. In one embodiment, for example, where the region map and the response map are identical, the system generates a confidence score of 1.000. In such an example, the environment data was gathered using a collection vehicle that was located at the same physical location with the same orientation of that of the system's vehicle. The confidence score reflects the system's confidence in the vehicle's predicted position compared to its position according to the region map, relative to the vehicle's lateral position within a lane. For example, a score of 1.000 correlates to a confidence of 100% and a score of 0.000 correlates to a confidence of 0%.

At step 260, the system outputs a predicted location. In one embodiment, the system may output the predicted location to an automated self-driving system. In another embodiment, the system may output the predicted location to an ADAS. In another embodiment, the system may output a corrected location if the confidence score is below a predetermined threshold. For example, the score threshold is set at 0.900. If the system generates a confidence score of anything less than 0.900, for example, a score of 0.85, the system generates a corrected location based on the comparison of the sampled region map and the response map. In an embodiment, the mathematical variance may be used as a confidence score. Further, if the system generates a confidence score of, for example, 0.950, the system outputs the vehicle's position as determined by the GPS/IMU information. In another embodiment, the system outputs the corrected location to an ADAS and/or an automated self-driving system. In another embodiment, the mathematical variance is used as the confidence score.

FIG. 3A illustrates an image taken by a single camera 120. Here, the camera 120 is facing the direction of travel. In other embodiments of the disclosure, the camera is positioned such that the view captured is not the direction of travel, e.g., facing behind the vehicle or to either side. In other embodiments of the disclosure, a plurality of cameras may be used. As disclosed herein, the camera may be installed anywhere on the vehicle having any orientation that allows the camera to view the vehicle's environment. When the camera is installed on the vehicle, the system may be updated as to the camera's positioning relative to the rest of the vehicle and the direction of travel. The system 100 analyzes the image taken by the camera and creates a response map by detecting lane markers such as sold lines 301, striped lines 303, and reflectors 302. In one embodiment, the camera may be permanently installed on the vehicle. For example, the camera may be integrated into the vehicle's rearview mirror or a bumper. In another embodiment, the camera may be temporarily installed on the vehicle. In another embodiment, the camera utilized may be included in a mobile device such as a cell phone or tablet. In such an embodiment, the mobile device may be temporarily installed on the vehicle and easily removed by a user.

FIG. 3B illustrates an exemplary response map according to an embodiment of the disclosure. The response map reflects lane markings as recognized by the system. For example, the response map is a binary map indicating lane markings 311 shown as black lines. In such an embodiment, the system analyzes the location information for lane indicators. When the system identifies a lane indicator, it plots a point on the response map (depicted as a black dot against a white background). Everything other than the relevant lane markings 311 are shown as white space 312. The system plots a plurality of lane indicators on the response map, culminating as lane markers 311. The system may also use physical structures such as bridges, barriers, signs, and buildings to determine lane markings.

In one embodiment, the computer 160 comprises computer-executable, non-transient code configured to detect certain elements with an image. For example, the computer 160 recognizes lane markings within a roadway including painted solid lines 301, painted striped lines 303, and reflectors 302. The system generates the response map as a series points, culminating a lane marking lines 311. The response map represents the road ahead of the vehicle, viewed from the camera 150 and perceived by the computer 160. In other embodiments, the lane markings 311 reflect other structural components such as bridges, signs, and barriers (not shown).

FIG. 3C illustrates a lane map, according to an embodiment of the present disclosure. The lane map comprises a comparison of the region map against the response map. The region map is compiled using images, GPS, radar, and/or LIDAR information. The system plots plurality of region map points 322 (shown as circles). The region map points 322 reflect lane markings as detected in the environment data 130. The response map comprises a plurality lines 321 (shown as grey lines) indicating the lane markers as viewed from the camera and perceived by the computer. The computer analyzes the differences between the region map and the response map and generates the vehicle's predicted location.

In another embodiment, the system determines a confidence score based on the differences in the lane map, which is shown in the top-left corner. For example, a perfect match overlays with 100% accuracy, resulting in a score of 1.000 (not shown). In another example, the system may determine a score of 0.74 where the overlay is a 74% match (as shown). In such an embodiment, the overlay is close, but the region map points 322 differs from the points from the response map lines 321 at some, but not all of the region map points 322. In such an embodiment, the score threshold may be 0.90, and in such an instance, the system would output a predicted vehicle location by analyzing the differences in the lane map. In another embodiment, the system may also determine other statistical parameters, such as the variance. In such an embodiment, the variance is calculated, for example, of 0.384 (as shown). For example, a logistic function may be used to calculate the variance, such as:

${variance} = \frac{x_{\min} + \left( {x_{\max} - x_{\min}} \right)}{1 + e^{S{({{Gx} - m})}}}$

where,

x_(min)=the minimum value

X_(max)=the maximum value

S=the steepness

G=the growth rate

x=the matching score of the response map

m=the midpoint

FIG. 4 illustrates an updated vehicle location, according to an embodiment of the present disclosure. The predicted location 401 is determined using GPS and/or IMU locating information. The GPS location 402 represents where the GPS perceives the vehicle to be relative to the lanes of travel. Notably, the GPS location 402 often varies greatly from the vehicle's actual location 403. Where the score is below a predetermined threshold, the system determines the predicted location 401 and outputs that location. In such an embodiment, the system recognizes which lane of traffic the vehicle is traveling. In other embodiments, the system determines the vehicle's predicted location 401 regardless of the confidence score. In other embodiments, the system may use the confidence score to determine the vehicle's predicted location 401.

Although a lane marking localization system has been shown and described, lane marking localization systems may be implemented according to other embodiments of the disclosure. For example, the system may utilize a plurality of cameras or other information gathering devices such as radar or LIDAR. Other embodiments of the disclosure may utilize a plurality of external or internal databases, on which relevant information is stored. Other embodiments also include those that output information to vehicle driving aids such as navigation and ADAS systems.

In an embodiment of the disclosure, the methodologies and techniques described herein are implemented on a special purpose computer programmed to determine lane marking and relative vehicle position. In an embodiment of the disclosure, the special-purpose computer comprises an embedded system with a dedicated processor equipped as part of a vehicle. In other embodiments, some or all of the components of the present disclosure may be integrated as part of a mobile device, for example, a cell phone or a tablet. The disclosure has been described herein using specific embodiments for the purposes of illustration only. It will be readily apparent to one of ordinary skill in the art, however, that the principles of the disclosure can be embodied in other ways. Therefore, the disclosure should not be regarded as being limited in scope to the specific embodiments disclosed herein, but instead as being fully commensurate in scope with the following claims. 

1. A method for determining a vehicle's location comprising: approximating the vehicle's region; receiving a region map from a database, wherein the region map corresponds to the vehicle's approximated region and comprises a plurality of region points indicating an expected roadway lane; receiving a response image generated by an imaging device, the response image comprising information relating to the vehicle's environment; generating a response map from the response image, the response map comprising a plurality of response points indicating the vehicle's location; comparing the response map to the region map; and predicting the vehicle's location based on the differences between the plurality of response points and the plurality of region points.
 2. The method of claim 1, wherein the vehicle's region is approximated using a Global Positioning System (GPS) device or an inertial measurement unit (IMU) device.
 3. The method of claim 1, wherein the generating the response map further comprises: detecting lane markers in the response image, the lane markers pertaining to physical aspects contained in the response image; and plotting the response points on the response map, the response points indicating locations of the lane markers.
 4. The method of claim 1, further comprising: generating, based on the differences, a confidence score.
 5. The method of claim 1, wherein the response image is generated from radar sensing equipment, light detection and ranging (LIDAR) sensing equipment, Global Positioning System (GPS) sensing information, and/or images.
 6. The method of claim 1, wherein the region map and the response map are compared at a selected frequency.
 7. The method of claim 6, wherein the selected frequency is at least 20 cycles per second.
 8. The method of claim 1, further comprising: outputting the vehicle's predicted location to an advanced driver-assistance system (ADAS).
 9. The method of claim 1, wherein each of the one or more imaging devices is adapted to perceive different aspects of the vehicle's environment.
 10. A system for determining a vehicle's location on a roadway, comprising: a locating device adapted to determine a vehicle's geographic region; a database comprising a plurality of region maps, each region map of the plurality of region maps comprising a plurality of region points; an imaging device adapted to perceive information relating to the vehicle's environment the imaging device comprising a camera that includes a depth sensor; a processor operably connected to the locating device, the database, and the imaging device, the processor, at a predetermined frequency, adapted to: receive, from the locating device, the vehicle's determined geographic region; receive, from the database, a region map from the plurality of region maps corresponding to the vehicle's determined geographic region; receive, from the imaging device, information perceived relating to the vehicle's environment; generate a response map, the response map comprising a plurality of response points corresponding to lane markers detected within the response map; compare the response map to the region map; and determine the vehicle's predicted location based on comparing the region map and response map.
 11. The system of claim 10, wherein the locating device comprises a Global Positioning System (GPS) device or an inertial measurement unit (IMU) device.
 12. The system of claim 10, wherein the imaging device further comprises a light detection and ranging (LIDAR) device.
 13. The system of claim 10, wherein the predetermined frequency is at least 20 cycles per second.
 14. The system of claim 10, wherein the processor is further configured to output the vehicle's predicted location to an advanced driver-assistance system (ADAS).
 15. The system of claim 10, wherein the processor is further configured to: determine, based on comparing the response map to the region map, a confidence score.
 16. The system of claim 10, further comprising a plurality of imaging devices, each adapted to perceive different aspects of the vehicle's environment.
 17. The system of claim 15, wherein the confidence score comprises a variance that is computed using a logistic function.
 18. The system of claim 17, wherein the variance is computed as: ${{variance} = \frac{x_{\min} + \left( {x_{\max} - x_{\min}} \right)}{1 + e^{S{({{Gx} - m})}}}},$ wherein x is a matching score of the response map, x_(min) is a minimum value of the response map, x_(max) is a maximum value of the response map, S is a steepness parameter, G is a growth rate parameter, and m is a midpoint of the response map.
 19. The system of claim 10, wherein the response map is generated using a camera pointing in a direction opposite to a direction of travel of the vehicle.
 20. A method for determining a vehicle's location, comprising: approximating the vehicle's region; receiving a region map from a database, wherein the region map corresponds to the vehicle's approximated region and comprises a plurality of region points indicating an expected roadway lane that was gathered by a collection vehicle equipped with lane sensing devices; receiving a response image generated by at least one imaging device of a plurality of imaging devices, wherein the at least one imaging device comprises a camera configured to capture ultraviolet light, and wherein the response image comprises information relating to the vehicle's environment; generating a response map from the response image, the response map comprising a plurality of response points corresponding to lane markers detected within the response map; comparing the lane markers in the response map to the expected roadway lane in the region map; and predicting the vehicle's location based on the differences between the plurality of response points and the plurality of region points. 